1. Field of the Invention
The present invention concerns a cathode of the type having a cathode head in which a surface emitter is arranged that emits electrons upon application of a heating voltage thereto.
2. Description of the Prior Art
A cathode of the above type in which the surface emitter has a rectangular footprint is known from DE 27 27 907 C2, for example. A surface emitter with a circular footprint is described in DE 199 14 739 C1. In the known surface emitters, a heating voltage is applied to the surface emitter during the operation of the x-ray tube, whereby electrons are emitted that are accelerated in the direction of an anode. X-ray radiation is generated in the surface of the anode upon impact of the electrons at the anode.
Such a surface emitter has a distinctly larger radiant surface usable for emission relative to the volume to be heated and in comparison to a filament emitter. The surface emitter therefore can be operated with a reduced working temperature relative to a filament emitter, so the service life of the cathode is increased.
The longer service life of a surface emitter due to the larger radiant surface (emission surface) requires a greater effort for cutoff of the emitted electron beam.
This beam cutoff by application of a negative voltage to the cathode head is necessary in many applications, in particular in applications with pulsed x-ray radiation. The more central regions of large-area surface emitters are geometrically farther removed from the electron accumulations generating the cutoff field at the cathode head, and thus can only be cut off by higher electron concentrations or higher field strengths. Higher field strengths, in turn, require larger minimum distances to be maintained to avoid arcing, as well as additional design costs.
An object of the present invention is to provide a cathode with a good cutoff capability.
The above object is achieved by a cathode according to the invention that has a cathode head in which a surface emitter is arranged that emits electrons upon application of a heating voltage, wherein the surface emitter is fashioned as a parallel surface emitter with at least two emitter surfaces spaced apart from one another, to which at least one electrically conductive cutoff electrode is fed that is galvanically separated from the parallel surface emitter. The emitter surfaces spaced apart from one another thus form partial emitters in the cathode according to the invention.
Multiple partial emitters connected in parallel, each partial emitter having a width of approximately 1 mm to 2 mm and being able to be grid-extinguished given a low cutoff voltage, are produced by the division of the surface emitter into at least two emitter surfaces as described above.
By fashioning the surface emitter as a parallel surface emitter with at least two emitter surfaces spaced apart from one another, and by feeding at least one electrically conductive cutoff electrode (that is galvanically separated from the surface emitter) to the surface emitter, the disadvantage of a poorer cutoff capability, or a cutoff capability that can only be achieved with a higher cutoff voltage, is remedied. The cathode according to the invention thus can be used for applications in which a fast cutoff capability of the electron emission is required. In spite of the fast cutoff capability, the cathode according to the invention also exhibits a long service life.
Higher field strengths for fast cutoff of the surface emitter that require greater minimum distances to be maintained to avoid arcing (as well as additional design measures) are thus not necessary in the cathode according to the invention.
In an embodiment of the invention, the cutoff electrode can lie at a cathode head potential, but this does not necessarily have to be the case. It is also possible for the cutoff electrode to be galvanically separated both from the surface emitter and from the cathode head, and thus at a different potential than the cathode head.
Depending on the design requirements or limit conditions for the cathode, the cutoff electrode can be fashioned as a barrier plate or as a barrier grid, in which case the cutoff electrode advantageously has a wire structure.
For example, a wire structure can be generated by wires that are soldered onto an insulator (for example ceramic) or are deposited on the substrate in a screening method.
If the cutoff electrode is executed as a barrier grid, at least one wire can be introduced between two adjacent emitter surfaces (for example given a surface emitter with rectangular emitter surfaces). It is also possible to span wires across the surface emitter, but this leads to a significant distortion of the electron beam and may, under the circumstances, entirely prevent the electron emission of the surface emitter. This can be avoided if the wires of the barrier grid are at a potential between the cathode potential and the anode potential (intermediate potential). Such an intermediate potential is naturally also possible for a cutoff electrode that is executed differently, for example a wire-like structure or barrier plate. The cutoff electrode need only be arranged so as to be electrically insulated from the cathode head and electrically insulated from the emitter surfaces.
In a further embodiment of the cathode according to the invention, the emitter surfaces of the parallel surface emitter are fashioned as a common component. For example, structures are cut from a plate with a laser to produce the parallel surface emitter. The parallel surface emitter produced in this way possesses at least two separate emitter surfaces (partial emitters) and—independent of the number of emitter surfaces—two small terminal legs. Such a surface emitter can be worked with just as simply as known emitters in terms of production and can be integrated into a cathode head.
However, for specific application cases it can also be advantageous for the emitter surfaces of a parallel surface emitter to be fashioned as separate components. In this case each emitter surface (partial emitter) has two small terminal legs so that the emitter surfaces can be activated separately.
A parallel surface emitter that has two emitter surfaces 2 and 3 (partial emitters) separated from one another and possesses two small terminal legs or lugs 4 and 5 at its ends is designated with 1 in
The emitter surfaces 2 and 3 are fashioned as a common component so that the emitter surfaces 2 and 3 thus lie at the same potential and thermionically emit electrons upon application of a heating voltage at the small terminal legs 4 and 5.
The surface emitter 1 can be processed just as simply as known surface emitters in terms of production. For example, the structures of the emitter surfaces 2 and 3 can be cut from a plate and be provided with incisions 2a, 2b, 3a and 3b with a laser.
The surface emitter 1 can be integrated into a cathode head 6, as is shown in
In the cathode head 6 shown in
The blocking voltage can be applied to the cathode head 6 (for example) when this has electrical contact with the cutoff electrode 7. In the event that the cutoff electrode 7 is arranged so as to be electrically insulated from the cathode head 6, the cutoff voltage is then directly applied to the cutoff electrode 7.
The cathode shown in the blocked state in
The parallel surface emitter 1 is at a cathode potential UK of −80 kV, for example.
The parallel surface emitter 1 in the shown exemplary embodiment possesses two emitter surfaces 2 and 3 separated from one another.
An electrically conductive cutoff electrode 7 that is galvanically separated from the parallel surface emitter 1 by an insulator arrangement 8 (for example Al2O3) is fed to the surface emitters 2 and 3. In the shown embodiment, the cutoff electrode 7 has a wire-like structure.
The cutoff electrode 7 can be connected to a cutoff voltage US that is more negative than the cathode potential UK=−80 kV. If the cutoff electrode 7 is connected to the cutoff voltage US, an exit of the negatively charged electrons from the cathode head 6 is reliably prevented. In the shown exemplary embodiment, US=−85 kV.
If the cutoff voltage is disconnected (US=UK+0 kV, thus US=−80 kV), the electrons can then flow through the cutoff electrode 7 in the direction of the anode. The cutoff electrode 7 can thus be connected between two potential levels, namely—80 kV and −85 kV.
As an optional embodiment, the cathode head 6 shown in
The electron focusing element 9 has an insulating frame 10 on which focusing wires 11 are arranged that can be connected via a connection wire 12 to a focusing voltage UF of (for example) −83 kV. The focusing wires 11 are arranged in a plate frame 13 in a simple manner (in terms of production).
In that the focusing voltage (UF=−83 kV) is more positive by 2 kV than the cutoff voltage (US=−85 kV) and more negative by 3 kV than the cathode potential (UK=−80 kV), the electrons are focused upon application of the focusing voltage.
If the cutoff electrode 7 is connected to the cutoff voltage US=−85 kV, the electron focusing element 9 is simultaneously connected to −80 kV. The electron focusing element 9 therefore does not affect the cutoff effect of the cutoff electrode 7.
The focusing voltage UF can thus be switched between two potential levels, namely −83 kV and −80 kV (cathode potential UK).
The aforementioned voltage values to be understood merely as examples. Other voltage values can also be realized without difficulty by those skilled in the art.
In the embodiment of the cathode according to the invention as presented in
A cathode according to
Although modifications and changes may be suggested by those skilled in the art, it is the intention of the inventors to embody within the patent warranted hereon all changes and modifications as reasonably and properly come within the scope of their contribution to the art.
Number | Date | Country | Kind |
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10 2008 046 721 | Sep 2008 | DE | national |
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Number | Date | Country |
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Number | Date | Country | |
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20100067663 A1 | Mar 2010 | US |